.

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leES Statutory Meeting 1991
IGES Marine Environmental Quality Gommittee
G.M.199IjE:23
.:.
MOLEGULAR
•
GEUlJLAR MARKERS OF POLUITANT EXPOSURE
AND
Michael N Moore
1,
David M Lowe
1,
David Rucke
2
LIVER DAKAGE IN FISH
AND
and Peter Dixon
2
1
Plymouth Marine Laboratory (NERG) , Gitadel HilI, Plymouth, UK
2
HAFF Fish Diseases Laboratory, Weymouth, UK
ABSTRACT
The
iden~ifica~ion
pathological
contaminan~s,
of early onset changes, which may
condi~ions
is
a
key
environmental pollution.
induced by
requiremen~
the
in
injurious
ultima~ely
effects
assessment
of
the
lead to
of chemical
effects
of
It is only by the mechanistic linking of changes in
molecular and subcellular processes with the later pathological alterations
tha~ i~
will be possible to establish causa I relationships.
One approach to
this pr~blem is ~he use of the tools provided by molecular cell biology. This
involves the use of molecular probes in live cells
targe~
organs.
such
as
liver,
coupled with
~echniques
specific macromolecules in cells or tissue sections.
, .....
facilitates
isola~ed
for
from potential
recognition
of
The use of these methods
the identification of early stages of cell
injury.
as weIl as
alterations which are restricted to small numbers of cells such as occur in
~he
early
s~ages
of
neoplas~ic
disease.
1
The cell surface membrane is oft:en t:he init:ial int:erface wit:h t:he environment:
and it: is here t:hat: changes
.,:,
.:
at:
t:he molecular level can
readily ident:ified,
such as increases or decreases in membrane-bound recept:ors.
t:he cell,
On moving int:o
t:he int:ernal membranous syst:ems such as t:he endocyt:ic-Iysosomal
apparat:us and t:he endoplasmic ret:iculum appear
processes leading
•
be
t:o
t:o
play major roles in
cell injury and at: t:his level it: is possible
relat:e
such changes
t:o
molecular
t:he t:issue level are described for t:he livers of flat:fish (dab)
t:o
t:he his t:opa t:hology.
t:o
following experiment:al exposure
dat:a for
t:o
exposure in t:he field.
Examples of linked alt:erat:ions from t:he
cont:aminat:ed sediment: and
compared wi t:h
In conclusion, t:he use of molecular and
cellular changes as biomarkers oE bot:h cont:aminant: exposure and cell damage in
impact: assessment: may have considerable pot:ent:ial,
part:icularly where
t:he
mechanist:ic basis oE t:he alt:erat:ions is weIl charact:erized.
INTRODUGTION
Flatfish are widely used as
indicators
damage by toxic chemical pollutants .
~
for
One
the detection of environmental
approach is
to
identify adverse
molecular and cellular reactions (biomarkers) to pollutant-induced liver ce11
injury in fish. 1 - 7 Such an approach is described in this paper and
focussed on the
is further
the investigation of the linking causal mechanisms involved
in molecular damage, cell injury and liver pathology.
The
aim of this
research is to derive a linked sequence of "diagnostic tools", which can be
...,. .
..
used as "early warning signals" of both exposure to and environmental damage
by toxic chemieals, in order to predict potential pathological consequences .
•
The 1iver was
chosen as
it
is
an integrator of many
functions
inc1uding
detoxication/activation of toxic chemieals, digestion and storage,
excretion
and synthesis of the egg yo1k protein vite110genin.
There
is
also a
considerab1e body of literature on po11utant chemica1 impact on the ce11u1ar
patho10gy of fish 1iver.'
The approach was based on the detection of mo1ecu1ar and ce1lular changes
resulting from chemical contamination.
The
identification of early onset
changes, which may ultimately lead to full-blown disease, is a key requirement
in assessment of the effects of environmental pollution.
Overtly diseased
fish are likely to be rapid1y e1iminated from the population, hence assessment
based on such fish may prove difficu1t and even if samp1es are avai1ab1e
higher level complications resulting from the primary lesion will be a
confounding factor.
"
In fact,
it is on1y through the mechanistic linking of
changes in mo1ecu1ar and ce11u1ar processes with the 1ater pathological
•
endpoints that it will be possible to establish causal relationships.
3
Cells are the functional building blocks of life.
As such, they consist of an
intricate network of molecular machinery which must
..•
function with a
degree of co-ordination to maintain the processes of life.
high
Disturbance to
part or parts of this molecular machinery will result in functional failure
'."
within parts of the cell which may then lead to a
cascade of effects
culminating in pathological change, such as ce11 death or tumour formation.
Cell biology
provides many tools with which to test for disturbances in cells
and the processes leading to liver disease.
•
fluorescent molecular probes
that can readily
The approach adopted he re uses
be inserted into live cells. 8
These probes are used to identify and study specific structural components
such as receptors or organelles ,as weIl as to
enzymic processes . 3.5
This
follow dynamic structural and
approach coupled with antibody recognition of
specific cellular molecules
(immunocytochemistry)
has been applied to
laboratory investigation of the effects of chemically contaminated sediments
on the livers of flatfish (dab, Limanda limanda).
MATERIALS AND METHODS
The experimental investigation involved the exposure of flatfish (body length
14-20.5 cm,
males and females)
total hydrocarbons)
hydrocarbons)
to either ci. contaminated sediment
(210 ppm
or a relatively clean reference sediment (75 ppm total
for aperiod of 144 days at field ambient temperatures.
The
sediment depth was approximate1y 15 cm and the partic1e size characteristics
of both sediments were very simi1ar. At the end of this period the fish were
•
ki1led
tissue
Part of the 1iver was used to prepare'
and their livers removed .
sections
for
cellular
patho1ogy and
4
antibody-recognition
tests
for
---- ----
clathrin (a protein involved in
---------~-----
the process of receptor-mediated endocytosis,
which imports specific extracellular substances into the ce1l) , low density
lipoprotein (LDL, a cholesterol rich lipid-protein complex used by the cell
.;
for synthesis of new membranes), cell surface receptor for epidermal growth
..•
factor (EGF, a chemical signal that triggers cell growth and division), and
ras-oncoprotein (the product of a
"cancer gene"). 4.9.10
The remainder of the
liver was used to prepare isolated hepatocytes (the main type of liver cell)
using a mechanical and enzymic process of disaggregation.
These individual
living ce1ls were then subjected to analysis using fluorescent molecular
probes for a range of structural and functional features.
~
These included
intracellular organelles, such as endoplasmic reticulum (ER), Golgi apparatus
and lysosomes,
cytochrome
P-450
associated enzymic
reactions
involved in
detoxication of contaminant chemicals (7-ethoxyresorufin-o-deethylase EROD and
3-cyano,7-ethoxycoumarin-o-deethylase CNECOD), production of chemically
reactive forms of oxygen (oxyradicals),
glutathione
(GSH) ,
which protects
against reactive xenobiotic derivatives and radicals, and, finally, processes
of bulk molecular uptake involving invagination of the cell surface
membrane
(endocytosis).5.9-16
Livers were excised and the hepatocytes were
isolated by mechanical
dissaggregation in a mixture of collagenase and lipase as described by Lowe et
al. (1992).
Isolated hepatocytes
(20JJl of cell suspension) were a1lowed to
attach to cleaned glass slides for 15 min at 15°C prior to exposure to the
probe solutions. All cells used in this study had a viability of >98% as
••
tested using eosin Y exclusion.
Fluorescent molecular probes used in this
study included 3, 3'-dihexyloxacarbocyanine iodide (DiOC 6(3»
hexyl
es~er
and rhodamine B
(R6) for ER, dihydrorhodamine 123 (DiHR123) for superoxide
radicals, 7-ethoxyresorufin for EROn, monochlorobimane for glutathione (GSH) ,
5
NBD-colcemid for microtubules, acridine orange for lysosomal integrity, Texas
Red conjugated albumin for endocytosis, Dil-low density lipoprotein (LDL-Dil)
·..
·•.
and BODlPY-concanavalin A (con A-BODlPY) for cell surface receptor binding.
With the exception of the albumin, LDL-Dil and con A-BODlPY all probes were
prepared as stock solutions in DMSO and used at a dilution of 10- 4 in cu1ture
medium (amended Hanks balanced salt solution).
5
The final concentrations and
incubation times were as follows :DiOG 6 (3), 10 min, 250ng.ml- 1 ; R6, 10 min, 250ng.ml- 1 ; 7-ethoxyresorufin, 10
min, 2.4~g.ml-l; dihydrorhodamine 123, 15 min, 43~M; monoch1orobimane, 10 min,
•
2300 ng.ml-1
ng. ml- 1
;
3-8.
NBD~colcemid, 10 min,
270ng.ml- 1 ; acridine orange, 10 min, 1000
The reaction for oxyradicals was stopped after 10 min by the
addition of N-t-butyl-a-phenylnitrone (PBN) to give a final concentration of
100mM.
5
Texas Red-albumin was dissolved directly in culture medium to
give
a final concentration of 40~g.ml-l and ce11s were incubated in this medium for
60 min at 20 o G. LDL-Dil and Gon A-BODlPY were added directly to the culture
medium and incubated for 10 min at final concentrations of 25~g.ml-l and
10~g.ml-l respectively.
All incubations were performed in the dark in a humidity chamber at l5°G.
•
Gell preparations were coverslipped,
sealed with a liquid paraffin-lanolin
mixture and epifluorescence images captured on high-resolution video tape for
subsequent analysis of fluorescence intensity.3
A~ FlTG filter-block was used
for visualising ER, oxyradical generation, lysosomes receptor-ligand binding
and microtubules; a blue-violet filter block was used for GNEGOD and GSH; a
• •
rhodamine block was used for EROD; and a Texas Red block was used for
endocYtosis. 3
6
A laserscan confocal microscope (SARASTRO / Molecular Dynamics) with Silicon
Graphics
imaging capabilities was
used
localization of the fluorescent bioprobes.
,
.
.
•
in
the
An
detailed study
of
the
additional probe was used to
test for ER; this was rhodamine B hexylester (R6) (250ng.ml- 1 , 10 min) , which
requires a rhodamine block for visualization (Teresaki, M., unpublished
data)
.11
Fluorescent emission was measured against sets of graded images for the
appropriate probe,
Graphics).
•
which were prepared using
Twenty cells (diameter 12 ±
l~m)
image
analysis
(Silicon
were measured per liver sampIe
and the Mann-Whitney U-test was used for statistical analysis of the data. In
the studies on endocytosis and presence of ras-oncoprotein cells, were scored
as being positive or negative. Data is presented as % of positive livers and
the Fisher exact probability test used in statistical analysis.
Immunocytochemical detection of clathrin, LDL and receptors for EGF was
performed on water-soluble methacrylate sections using polyclonal antibodies
with appropriate controls
(Lowe,
unpublished data).
The ras-oncoprotein was
tested for using frozen sections fixed in methanol for 10 min using a
polyclonal antibody for N-ras-oncopeptide. 4 All
~
three methods employed the
fluorescent second antibody technique. 4
RESULTS
The results showed that the two probes used to detect endoplasmic reticulum in
• -
the hepatocytes both had the
same
type
of distribution in a
lamellar network as demonstrated using confocal imaging.
tubular and
This finding
supports the premise that the probes are localising in the ER and not in other
7
intrace11u1ar structures. Fluoresence produced by EROO activity and
s~peroxide
generation showed some apparent association with the ER but the distribution
was often diffuse. Monochlorobimane reacts specifica11y with glutathione (GSH)
....
•
and, here,
the fluorescence showed diffuse 10ca1ization in the cytoplasm. l1
Fluorescence for NBO-colcemid binding to microtubules tended to be distributed
throughout the cytoplasm. Acridine orange fluoresces orange-red in lysosomes
due
to
proton
trapping
and
subsequent
po1yanionic
binding .
At
low
concentrations of trapping and binding the fluorescence is green. Texas Redalbumin was localized in vesicles be1ieved to be endosomes and possib1y also
some lysosomes.
..
The resu1ts of the experimental investigation showed evidence of major
molecu1ar disturbances within the 1iver ce1ls of fish exposed to contaminated
sediment (Figs. 1-3). These inc1uded a proliferation of endoplasmic reticulum
membrane, an increase in the activity of the associated detoxication enzymes
(EROO and CNECOO),
a
decrease in intracellular glutathione,
Golgi system which is central to
the
atrophy of the
intracellular vesicular
transport of
proteins, as weIl as 10ss of integrity of the 1ysosoma1system (important in
the processing of macromolecu1es ingested by endocytosis and in the recycling
of cellular constituents).
Additional changes included a marked reduction in
non-specific endocytosis and an increase
in c1athrin and ce11 surface
receptors for binding epidermal growth factor
(EGF) and LDL (Fig.
3).
The
amount of endocytosed LDL was also great1y increased in the 1iver ce11s.
A positive reaction for ras-oncoprotein was detected in sma1l groups of liver
ce11s in all 1ivers from both reference and exposed fish. The intensity of the
•
fluorescence was stronger in the exposed fish .
•
8
DISCUSSION
The results show that relatively subtle changes within cells can be identified
and these are helping in the construction of a mechanistic picture of the
pathological
•
processes
polychlorinated biphenyls
(PAHs)
induced
by
(PCBs)
chemical
contaminants
and polycyclic
such
as
aromatic hydrocarbons
.3-6
Molecular probes inserted into live iso la ted liver cells showed biochemical
•
alterations as weIl as changes in some of the membranous compartments within
the liver cells.
reticulum (ER)
These included an increase in the amount of endoplasmic
in liver cells of contaminant exposed fish.
The ER is
responsible for manufacture of proteins and detoxication of xenobiotics
organic chemical contaminants).
(ie
Activity of two ER associated detoxication
enzymes, CNECOD and EROD, were significantly elevated in live cells from the
contaminant exposed fish. Elevated activity of this enzyme is widely accepted
as a likely biomarker of exposure to toxic xenobiotics. 17
A consequence of
xenobiotic exposure is the oxidative stress imposed on animals as a result of
one-electron metabolism giving rise
xenobiotics
can
be
metabolised
to
to
oxyradicals. 13
redox-cycling
Also,
many organic
intermediates
which
proliferate the production of oxyradicals. 18 Oxyradicals are also believed to
be a major factor in attacking intracellular components which results in cell
injury.18.19
here
,
-
•
•
However, it is not possible on the basis of the data presented
to directly link the
cellular injury,
increase
in oxyradical production with observed
although it is possible that reported lysosomal damage in
these fish, described below, may have been caused by such a mechanism.
Another membranous compartment,
the lysosomes, was also adversely affected.
9
Lysosomes
are
responsible
for
degrading and recycling both endogenous
exogenous macromolecules and are highly sensitive
xenobiotics and metals. 1 - 3 • 5
'~
•
to
the
toxic effects
and
of
The functional integrity of this compartment was
significantly impaired in the contaminant exposed fish .
The lysosomal compartment is closely linked with the Golgi apparatus, which
•
packages newly synthesised proteins and targets
them to
their correct
destination, and the endocytic system (responsible for bulk transport into the
cell by invagination of the ce II surface).
macromolecules
~
from
the
cell
surface
to
The endocytic system transports
the
lysosome
for
degradation and
involves a complex molecular sorting system for the recycling of cell surface
receptors.
Non-specific endocytosis
of labelled protein was
reduced in cells from exposed fish.
significantly
However, there was a marked increase in
the cellular content of a special form of fat
(lipid) known as low-density
lipoprotein (LDL); this LDL enters the cell by endocytosis following binding
to a specific cell surface receptor.
The inference is that endocytosis of LDL
is enhanced and this in turn contributes to the accumulation of LDL observed
in the liver cells of exposed fish.
Much of this
lipid accumulation was
associated with enlarged lysosomes and constitutes a toxic lipidosis (Kohler,
pers .. comm. ) .
Ihis type of degenerative change appears to be an important
step on the path to liver disease.'
An increase in cell surface receptors for epidermal growth factor (EGFstimulates cell growth)
in exposed fish may be indicative of attempted
regeneration of the damaged liver.,·9
like LDL,
•
Once again,
the EGF-receptor complex,
enters the cell by receptor-mediated endocytosis. 9
This type of
endocytosis requires a specific protein (clathrin), which is also elevated in
exposed fish. 9
10
These findings clearly demonstrate degenerative changes in liver cells from
the contaminant exposed fish. Lysosomal damage, Golgi atrophy, accumulation of
..
-
LDL, lysosomal enlargement, toxic lipidosis and a positive reaction for rasoncoprotein are all biomarkers of liver degeneration in the dab used in this
study.
The increased endoplasmic reticulum,
activity
together with
the
its associated EROD and CNECOD
depletion of glutathione
are
considered to be
probable biomarkers of exposure to contarninant xenobiotics.
The presence of
ras-oncoprotein in the liver cells of 'reference fish indicates either prior
exposure
~
of the
animals
in the
field
or,
else more
likely,
a
sufficient
xenobiotic content in the reference sediment.
The conclusion is that fish from the contaminant exposed group were impacted
by organic xenobiotics which induced proliferation of ER and
and CNECOD in the liver cells.
Furthermore ,
increas~s
the cells were
in EROD
injured in a
manner which is comparable to xenobiotic and radical attack in mammalian cells ,
and damage to the liver was of such an extent as to 'impair,integrated
function.
3
The results, obtained from the' use of the fluorescent molecular
probes described above indicates their potential in identifying molecular and
subcellular biomarkers of xenobiotic-induced cell
cells.
are consistent with those
techniques could be readily modified for
fluorescence microtitre reader.
..
in
isolat~d
liver
The methods used in this study have already been used in 'the field and
the findings
,.
in~ury
of the present study. 3-6 Such
larger scale biomonitoring using a
This would permit
the
rapid screening of
large numbers of sampIes and microscopy would only be required for cell
counts, viability tests and to validate the localization of the fluorescence.
".•
The immunocytochemical techniques could be readily applied to routine sampIes
for histopathology' and would greatly extend the inforrnational content, for a
11
1itt1e extra work.
This work was supported by the Department of the
Acknow1edgements.
,
.
•
Environment (U.K.) (PECD Ref. 7/8/137) .
...
REFERENCES
1.
Kohler, A.
Mar. Environ. Res., 28, 417-424 (1989).
2.
Moore, M.N.
Histochem. J., 22, 187-191 (1990).
3.
Moore, M.N.
Mar. Environ. Res., In Press (1991).
4.
Moore, M.N. & Evans, B.
Mar. Environ. Res., In Press (1991).
5. Lowe, D.M., Moore, M.N. & Evans, B.
Mar. Ecol. Prog. Ser., In Press
(1992)
6.
Simpson, M.G.
Mar. Environ. Res., In Press (1991).
7.
Hinton,
&
D.E.
Lauren,
D.J.
In Biomarkers
of
Environmental
Contamination (Eds. J.F. MCCarthy and L.R. Shugart), pp. 17-57. Lewis
Publishers, Boca Raton, Florida (1990).
8.
Moore, M.N. & Simpson, M.G.
9.
Darnell , J., Lodish, H. & Ba1timore, D. Molecular Cell Biology, 1105p.
Aquatic Toxicol., In Press (1992).
Scientific American Books, New York (1990).
10.
"'
•
DeBasio, R., Bright, G.R., Ernst, L.A., Waggoner, A.S. & Taylor, D.L.
J. Cell Biol., lOS, 1613-1622 (1987).
•
11.
Teresaki, M., Chen, L.B.
& Fujiwara, K.
12
J. Ce11 Bio1., 103, 1557-1568
(1986).
12.
White, I.N.H.
13.
Winston, G.W., Moore, M.N., Straatsburg, I. & Kirchin, M.
Arch.
Environ. Contarn. Toxico1., In Press (1991).
..
,
Anal. Bioehern., 172, 304-310 (1988).
14.
Rice, G.C., Bump, E.A., Shrieve, D.C., Lee, W. & Kovacs, M.
Cancer
Res., 46, 6105-6110 (1986).
15.
Hiratsuku, T. & Kato, T.
16.
Haug1and, R.P . . In : Mo1ecu1ar Probes - Handbook of F1uorescent Probes
J. Bio1. Chern., 262, 6318-6322 (1987).
and Research Chemica1s, pp. 125-127.
Mo1ecu1ar Probes, Inc., Eugene
(1989).
17.
Stegernan, J.J. & K1oepper-Sams, P.J.
Environ. Hea1th Perspect., 71,
87-95 (1987).
18.
DiGiu1o, R.T., Washburn, P.C., Wenning, R.J., Winston, G.W. & Jewe1,
C.S.
19.
Environ. Toxico1. Chern.,
Stier, A.
1103-1123 (1989).
In : Biochemica1 Mechanisrns of Liver Injury (Ed.
Slater), pp. 219-364.
Academic Press, London, New York (1978).
, ...
.•
.
•
~,
13
T. F.
Figure Legends
Fig. 1.
.
Biotransformation of Xenobiotics: Fluorescent molecular probes in
liver cells of fish exposed to contaminated sediment
·.
(210 ppm
total hydrocarbons; exposed) and reference sediment (75 ppm total
·.
hydrocarbons; control) for 144 days. Parameters measured include
~
endoplasmic
reticulum
(ER),
the
detoxication enzymes
CNECOD, oxyradicals (OXYRAD) and glutathione (GSH).
statistically significant difference
(P < 0.05,
* -
EROD
and
indicates
mean and SEM,
n-10) from the control.
Fig. 2.
Organelles:
Fluorescent molecular probes in liver cells of fish
treated as in Fig. 1. Parameters measured include lysosomal
integrity,
Golgi membranes and microtubules.
statistically significant difference
(P
* -
indicates
< 0.05, mean and
SEM,
n-lO) from the control.
Fig. 3.
Endocytosis: Fluorescent molecular probes in liver cells of fish
treated as in Fig. 1.
Parameters measured include incidence of
liver cell samples showing a positive reaction for non-specific
invagination of Texas Red albumin
(ENDOCYT),
cell surface
receptors for low density lipoprotein (LDL REC) and concanavalin
A (CON A REC).
* -
indicates statistically significant difference
(P < 0.002, Fisher exact probality test, n-10) from the control .
..,;
•
•
14
...
"\
e
J
-
e
....
,
, l·
biotr ansfor mation
*
300 ,---------+------------~
control
250 ----------------------------------
-
-----------------------------------------------
exposed
e
+-'
c
200---------------------------------------
o
u
'+-
o
~
(f)
o
100 --------
50 -----
0'--ER
EROD
CNECOD
test
OXYRm
GSH
"<r"
•
-'- l
e
~.
f
t
e
.
.
to-'~ " ~.
organelles
120...-----------------==--------
~
control
100 .------.
exposed
e
+-'
c
80 ._....__...-
o
u
'+-
o
~
60~-
(f)
o
40~-
o
L-..-.--_
LYSOS
GOLGI
test
MICTUB
-
e
endocytosis
120,--------------------------,
control
100 - -----exposed
80 ---..-------
-._---_.._._ _--_.- _. _---------*..__..__.- . _ --_ _---_ __---_ ---
GJ
U
c:
GJ
-0
U
c:
60---------···
40 --.-------.
20 .--.-------.
0'---ENDOCYr
LDL REC
test
CON A REC
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